Method to control the execution of a shift to a higher gear with a released accelerator pedal in a drivetrain provided with a dual-clutch, servo-assisted transmission

ABSTRACT

A method to control the execution of a shift to a higher gear with a released accelerator pedal in a drivetrain provided with a dual-clutch, servo-assisted transmission, comprising the steps of: opening, in a first instant, an outgoing clutch; closing, in the first instant, an incoming clutch; synchronizing, between a second instant and a third instant, a rotation speed of the internal combustion engine with a rotation speed of the incoming clutch, namely with the rotation speed imposed by the gear ratio of the following gear; completely opening, in the third instant, the outgoing clutch; completely closing, in the third instant, the incoming clutch; keeping the torque transmitted by the outgoing clutch constant between the second instant and a fourth instant; and keeping the torque transmitted by the incoming clutch constant between the second instant and the fourth instant.

CROSS-REFERENCE TO RELATED APPLICATIONS

This Patent Application claims priority from Italian Patent Application No. 102019000017543 filed on Sep. 30, 2019, the entire disclosure of which is incorporated herein by reference.

TECHNICAL FIELD

The invention relates to a method to control the execution of a shift to a higher gear with a released accelerator pedal in a drivetrain provided with a dual-clutch, servo-assisted transmission (namely, a gear shift in which the following or incoming gear is higher than the previous or outgoing gear).

PRIOR ART

A drivetrain provided with a dual-clutch, servo-assisted transmission comprises a pair of primary shafts, which are coaxial to one another, are independent of one another and are inserted inside one another; two coaxial clutches, each designed to connect a respective primary shaft to a drive shaft of an internal combustion engine; and at least one secondary shaft, which transmits the motion to the drive wheels and can be coupled to the primary shafts by means of respective gear trains, each defining a gear.

During a gear shift, the current gear couples the secondary shaft to a primary shaft, while the following gear couples the secondary shaft to the other primary shaft; as a consequence, the gear shift takes place by crossing the two clutches, namely by opening the clutch associated with the current gear and by simultaneously closing the clutch associated with the following gear.

Currently, a shift to a higher gear with a released accelerator pedal entails opening the outgoing clutch (namely, the clutch associated with the previous gear), decreasing the rotation speed of the internal combustion engine due to the braking torque generated by the internal combustion engine operating in engine braking mode and, finally, closing the incoming clutch (namely, the clutch associated with the following gear). In this way, the synchronization (decrease) of the rotation speed of the internal combustion engine with the speed imposed by the following gear (namely, by the incoming clutch) takes place when both clutches are open, thus causing the internal combustion engine to operate in engine braking mode (namely, the internal combustion engine is in cut-off condition and operates as engine brake, generating a braking torque).

This mode of execution of a shift to a higher gear with a released accelerator pedal is critical from the control point of view since the step of adjusting the rotation speed of the internal combustion engine is completely assigned to the sole internal combustion engine, as both clutches are kept open; it often happens that the rotation speed of the internal combustion engine decreases too much in order to then be synchronized with a sudden increase, thus generating a first forward pull and subsequently a strong backward pull in the moment in which the rotation speed of the internal combustion engine tries and increase again so as to reach the rotation speed of the incoming clutch (as a consequence, the overall sensation perceived by drivers is not very comfortable).

U.S. Pat. No. 6,881,171B2 describes a method to control the execution, in a drivetrain provided with a dual-clutch, servo-assisted transmission, of a gear shift during which the torque at the output of the transmission is kept constant or monotonically changing or the longitudinal acceleration of the vehicle is caused to monotonically change.

DESCRIPTION OF THE INVENTION

The object of the invention is to provide a method to control the execution of a shift to a higher gear with a released accelerator pedal in a drivetrain provided with a dual-clutch, servo-assisted transmission, said method not suffering from the drawbacks discussed above and, at the same time, being easy and economic to be implemented.

According to the invention there is provided a method to control the execution of a shift to a higher gear with a released accelerator pedal in a drivetrain provided with a dual-clutch, servo-assisted transmission, according to the appended claims.

The appended claims describe preferred embodiments of the invention and form an integral part of the description.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be described with reference to the accompanying drawings, showing a non-limiting embodiment thereof, wherein:

FIG. 1 is a schematic plan view of a rear-wheel drive road vehicle provided with a drivetrain with a dual-clutch, servo-assisted transmission, which is controlled according to the control method of the invention;

FIG. 2 is a schematic view of the drivetrain of FIG. 1; and

FIGS. 3 and 4 show the time development of the torques transmitted by the two clutches of the dual-clutch transmission, of the rotation speed of a drive shaft of the internal combustion engine, of the longitudinal deceleration of the road vehicle and of the torque generated by the internal combustion engine during respective shifts to a higher gear carried out with the control method according to the invention.

PREFERRED EMBODIMENTS OF THE INVENTION

In FIG. 1, number 1 indicates, as a whole, a road vehicle (in particular, a car) provided with two front driven (namely, non-drive) wheels 2 and with two rear drive wheels 3. In a front position there is an internal combustion engine 4, which is provided with a drive shaft 5, which produces a torque T_(E), which is transmitted to the drive wheels 3 by means of a drivetrain 6. The drivetrain 6 comprises a dual-clutch, servo-assisted transmission 7 arranged in the rear-wheel-drive assembly and a transmission shaft 8, which connects the drive shaft 5 to an input of the dual-clutch, servo-assisted transmission 7. The dual-clutch, servo-assisted transmission 7 is connected, in a train-like manner, to a self-locking differential 9, from which a pair of axle shafts 10 start, each integral to a drive wheel 3.

The road vehicle 1 comprises a control unit 11 of the internal combustion engine 4, which controls the internal combustion engine 4, a control unit 12 of the drivetrain 6, which controls the drivetrain 6, and a BUS line 13, which is manufactured, for example, according to the CAN (Car Area Network) protocol, extends to the entire road vehicle 1 and allows the two control units 11 and 12 to communicate with one another. In other words, the control unit 11 of the internal combustion engine 4 and the control unit 12 of the drivetrain 6 are connected to the BUS line 13 and, therefore, can communicate with one another by means of messages sent through the BUS line 13. Furthermore, the control unit 11 of the internal combustion engine 4 and the control unit 12 of the drivetrain 6 can be directly connected to one another by means of a dedicated synchronization cable 14, which is capable of directly transmitting a signal from the control unit 12 of the drivetrain 6 to the control unit 11 of the internal combustion engine 4 without the delays caused by the BUS line 13. Alternatively, the synchronization cable 14 could be absent and all communications between the two control units 11 and 12 could be exchanged using the BUS line 13.

According to FIG. 2, the dual-clutch, servo-assisted transmission 7 comprises a pair of primary shafts 15, which are coaxial to one another, independent of one another and inserted inside one another. Furthermore, the dual-clutch, servo-assisted transmission 7 comprises two coaxial clutches 16, each designed to connect a respective primary shaft 15 to the drive shaft 5 of the internal combustion engine 4 through the interposition of the transmission shaft 8; each clutch 16 is an oil bath clutch and, hence, is pressure-controlled (i.e. the degree of opening/closing of the clutch 16 is determined by the pressure of the oil inside the clutch 16); according to an alternative embodiment, each clutch 16 is a dry clutch and, hence, is position-controlled (i.e. the degree of opening/closing of the clutch 16 is determined by the position of a movable element of the clutch 16). The dual-clutch, servo-assisted transmission 7 comprises one single secondary shaft 17 connected to the differential 9 that transmits the motion to the drive wheels 3; according to an alternative and equivalent embodiment, the dual-clutch, servo-assisted transmission 7 comprises two secondary shafts 17, both connected to the differential 9.

The dual-clutch, servo-assisted transmission 7 has seven forward gears indicated with Roman numerals (first gear I, second gear II, third gear III, fourth gear IV, fifth gear V, sixth gear VI and seventh gear VII) and a reverse gear (indicated with R). The primary shaft 15 and the secondary shaft 17 are mechanically coupled to one another by a plurality of gear trains, each defining a respective gear and comprising a primary gear wheel 18 fitted on the primary shaft 15 and a secondary gear wheel 19 fitted on the secondary shaft 17. In order to allow for a correct operation of the dual-clutch, servo-assisted transmission 7, all odd gears (first gear I, third gear III, fifth gear V, seventh gear VII) are coupled to a same primary shaft 15, whereas all even gears (second gear II, fourth gear IV and sixth gear VI) are coupled to the other primary shaft 15.

Each primary gear wheel 18 is splined to a respective primary shaft 15, so as to always rotate with the primary shaft 15 in an integral manner, and permanently meshes with the respective secondary gear wheel 19; on the other hand, each secondary gear wheel 19 is mounted on the secondary shaft 17 in an idle manner. Furthermore, the dual-clutch, servo-assisted transmission 7 comprises four synchronizers 20, each mounted coaxial to the secondary shaft 17, arranged between two secondary gear wheels 19 and designed to be operated so as to alternatively fit the two respective secondary gear wheels 19 to the secondary shaft 17 (i.e. so as to alternatively cause the two respective secondary gear wheels 19 to become angularly integral to the secondary shaft 17). In other words, each synchronizer 20 can be moved in one direction to fit a secondary gear wheel 19 to the secondary shaft 17 or can be moved in the other direction to fit the other secondary gear wheel 19 to the secondary shaft 17.

The dual-clutch transmission 7 comprises one single secondary shaft 17 connected to the differential 9 that transmits the motion to the drive wheels 3; according to an alternative and equivalent embodiment, the dual-clutch transmission 7 comprises two secondary shafts 17, both connected to the differential 9.

According to FIG. 1, the road vehicle 1 comprises a passenger compartment housing a driving position for the driver; the driving position comprises a seat (which is not shown), a steering wheel 21, an accelerator pedal 22, a brake pedal 23 and two paddle shifters 24 and 25, which control the dual-clutch, servo-assisted transmission 7 and are connected to the opposite sides of the steering wheel 21. The upshift paddle shifter 24 is operated by the driver (by means of a short pressure) in order to request an upshift (namely, the engagement of a new gear, which is higher than the current gear and contiguous with the current gear), whereas the downshift paddle shifter 25 is operated by the driver (by means of short pressure) in order to request a downshift (namely, the engagement of a new gear, which is lower than the current gear and is contiguous with the current gear).

Hereinafter there is a description of the modes of execution of an upshift with a released accelerator pedal 22 from a current, lower gear A to a following, higher gear B (when the accelerator pedal 22 is released, the internal combustion engine 4 operates in cut-off condition and acts as engine brake); namely, the current gear A has a smaller gear ratio than the following gear B (hence, given the same speed of the road vehicle 1, the current gear A causes the internal combustion engine 4 to run more quickly than the following gear B).

In an initial situation (i.e. before the gear shift), an outgoing clutch 16B is closed in order to transmit the motion to a primary shaft 15A, which, in turn, transmits the motion to the secondary shaft 17 through the current gear A, which is engaged; an incoming clutch 16B, on the other hand, is open and, hence isolates a primary shaft 15B from the transmission shaft 8. Before beginning the upshift, the following gear B is engaged in order to connect, through the gear B, the primary shaft 15B to the secondary shaft 17. When the driver sends the gear shift command, the gear shift is carried out by opening the outgoing clutch 16A in order to disconnect the primary shaft 15A (hence, the gear A) from the transmission shaft 8 (i.e. from the drive shaft 5 of the internal combustion engine 4) and, (more or less) simultaneously, by closing the incoming clutch 16B in order to connect the primary shaft 15B (hence, the gear B) to the transmission shaft 8 (i.e. to the drive shaft 5 of the internal combustion engine 4).

FIG. 3 shows the ways in which a shift to a higher gear is carried out, the driver sending the upshift command by acting upon the upshift paddle shifter 24 while the accelerator pedal 22 is released. FIG. 3 shows, starting from the top:

a first diagram showing the time development of the rotation speed ω_(E) of the internal combustion engine 4, the rotation speed ω_(A) of the outgoing clutch 16A and the rotation speed ω_(B) of the incoming clutch 16B;

a second diagram showing the time development of the torques T_(A) and T_(B) transmitted by the two clutches 16A and 16B;

a third diagram showing the time development of the torque T_(E) generated by the internal combustion engine 4 (before and after the upshift the internal combustion engine 4 is in cut-off condition and, hence, operates in engine braking mode generating a negative torque T_(E)); and

a fourth diagram showing the time development of the longitudinal acceleration α of the vehicle 1 (it should be pointed out that the longitudinal acceleration α of the vehicle 1 always is negative, namely the vehicle 1 is slowing down as the internal combustion engine 4 is generating a negative torque T_(E), namely is braking, thus operating in engine braking mode).

As soon as the control unit 12 of the drivetrain 6 receives the gear shift command from the driver (instant t₀), the control unit 12 of the drivetrain immediately starts filling the incoming clutch 16B, namely it immediately starts feeding oil under pressure into the incoming clutch 16B; indeed, the incoming clutch 16B associated with the following gear B can transmit a significant torque to the rear drive wheels 3 only when the filling with oil under pressure has been completed and, hence, the oil under pressure, for it cannot occupy further volume inside the incoming clutch 16B, exerts a thrust that packs the discs of the incoming clutch 16B. As a consequence, before the incoming clutch 16B associated with the following gear B can actually start transmitting a significant torque to the rear drive wheels 3, it is necessary to wait for a given delay time interval (typically ranging from 80 to 220 thousandths of second), during which the filling of the incoming clutch 16B with oil is completed. The completion of the filling of the incoming clutch 16B is normally monitored through a pressure sensor, which detects the pressure of the oil inside the incoming clutch 16B: when the pressure of the oil inside the incoming clutch 16B exceeds a predetermined threshold, this means that the inner volume of the incoming clutch 16B was completely filled and, hence, the oil inside the clutch 16B starts compressing. As a consequence, the instant t₁ in which (after the delay time has elapsed) the incoming clutch 16B is filled with oil and is ready to transit a significant torque is established when the pressure of the oil inside the incoming clutch 16B exceeds the predetermined threshold.

From the instant t₀, in which the control unit 12 of the drivetrain immediately starts closing the incoming clutch 16B, to the instant t₁, in which, after the delay time has elapsed, the incoming clutch 16B is filled with oil and is ready to transmit a significant torque, nothing happens to the dynamic of the road vehicle 1, i.e. the entire torque T_(E) generated by the internal combustion engine 4 (which is a negative torque T_(E), namely a braking torque T_(E), since the internal combustion engine 4 is in cut-off condition and, hence, operates as engine brake) is entirely transmitted by the outgoing clutch 16A, like before the beginning of the gear shift. In the instant t₁, the incoming clutch 16B starts transmitting a torque T_(B) (namely, the torque T_(B) starts increasing) and, at the same time, the outgoing clutch 16A is ordered to open (namely, the torque T_(A) starts decreasing); it should be pointed out that the opening of the outgoing clutch 16A associated with the current gear A takes place with no delay as the outgoing clutch 16A is already filled with oil under pressure and, in this phase, it simply needs to be emptied from part of the oil by opening a solenoid valve (whose action, thus, is instantaneous).

Between the instants t₁ and t₂ there is a partial transfer of torque between the clutches 16A and 16B: the torque T_(A) transmitted by the outgoing clutch 16A decreases with a linear ramp between the instants t₁ and t₂ and in the instant t₁ the torque transmitted by the incoming clutch 16B increases in a step-like manner (by a quantity which is smaller than the overall decrease in the torque T_(A) transmitted by the outgoing clutch 16A). Subsequently, between the instants t₂ and t₃, the torques T_(A) and T_(B) transmitted by the two clutches 16A and 16B remain constant and, in this amount of time, the torque T_(A) transmitted by the outgoing clutch 16A is greater than the torque T_(B) transmitted by the incoming clutch 16B.

Subsequently, between the instants t₃ and t₄ there is a complete transfer of torque between the two clutches 16A and 16B, i.e. the torque transmitted by the outgoing clutch 16A progressively decreases up to zero (the outgoing clutch 16A is opened by means of a linear ramp) and, at the same time, the torque transmitted by the incoming clutch 16B progressively increases (the incoming clutch 16B is closed by means of a linear ramp), thus determining a crossing between the two clutches 16A and 16B. The clutches 16A and 16B are opened and closed by means of linear ramps, namely the respective torques T_(A) and T_(B) change over time (decreasing and increasing) with linear variation laws.

The outgoing clutch 16A is completely opened in the same amount of time needed to completely close the incoming clutch 16B; therefore, in the instant t₄ the outgoing clutch 16A is completely open (i.e. does not transmit a torque any longer), whereas the incoming clutch 16B is completely closed (i.e. transmits the entire torque T_(E) of the internal combustion engine 4). Between the instants t₁ and t₄ there is the shifting time, during which the torque transmitted by the outgoing clutch 16A decreases until it becomes zero and, simultaneously, the torque transmitted by the incoming clutch 16B increases until it reaches the torque T_(E) generated by the internal combustion engine 4 (as already mentioned above, the internal combustion engine 4 is in cut-off condition and, hence, operates as engine brake, thus generating a negative torque T_(E)), namely during which the outgoing clutch 16A separates itself from the drive wheels 3 and the incoming clutch 16B gets connected to the drive wheels 3.

The rotation speed ω_(E) of the internal combustion engine 4 is equal to the rotation speed ω_(A) imposed by the gear ratio of the current gear A before the gear shift until the instant t₂, it progressively decreases towards the rotation speed ω_(B) imposed by the gear ratio of the following gear during the gear shift and is equal to the rotation speed ω_(B) after the gear shift.

Between the instants t₂ and t₄ there is the synchronization time, during which the rotation speed ω_(E) of the internal combustion engine 4 decreases from the rotation speed ω_(A) imposed by the gear ratio of the current gear A to the rotation speed ω_(B) imposed by the gear ratio of the following gear B, namely the rotation speed ω_(E) is synchronized with the rotation speed ω_(B). In order to decrease the rotation speed ω_(E) of the internal combustion engine 4, the negative (namely, braking) torque T_(E) generated by the internal combustion engine 4 is used between the instants t₂ and t₄.

The longitudinal acceleration α of the vehicle 1 is approximately constant and equal to the value α_(A) (which is negative, since the vehicle is slowing down) immediately before the gear shift and is approximately constant and equal to the value α_(B) (which is negative, since the vehicle is slowing down, and smaller than the value α_(B) in absolute value) immediately after the gear shift. During the gear shift, the longitudinal acceleration of the vehicle 1 progressively increases from the initial value α_(A) to the final value α_(B).

In the embodiment shown in FIG. 3, the internal combustion engine 4 is in cut-off condition before the upshift (hence, it operates as engine brake generating a braking torque T_(E)) and continues being in a cut-off condition even after the upshift; namely, before, during and after the upshift the driver keeps the accelerator pedal 22 completely released. However, it can happen that the driver, after having requested the upshift (namely, after the instant t₀), decides to press the accelerator pedal 22, thus requesting that the internal combustion engine 4 generates a positive torque T_(E) (namely, a drive torque); this situation is present in the embodiment shown in FIG. 4, in which in the instant t₅ (for example placed between the instant t₂ and the instant t₃) the driver, after having requested the upshift (namely, after the instant t₀), presses the accelerator pedal 22. Obviously, the control unit 12 of the drivetrain 6 must anyway complete the upshift that has already started, but can try and give an immediate response to the new (and unpredicted) request of the driver, so as to give the driver a feeling of extreme responsiveness; as a consequence, starting from the instant t₃ (subsequent to the instant t₅), the control unit 12 of the drivetrain 6 requests that the control unit 11 of the internal combustion engine 4 increases the torque T_(E) generated by the internal combustion engine 4 (according to the request of the driver, who pressed the accelerator pedal 22) and, at the same time, accelerates the closing of the incoming clutch 16B (namely, makes the closing of the incoming clutch 16B faster), which, obviously, now has to transmit, as a whole, a greater torque T_(B) due to the fact that the internal combustion engine 4 was turned on.

In other words, the control unit 12 of the drivetrain 6 increases, in case the accelerator pedal 22 is pressed by the driver during the upshift in the instant t₅ (which is subsequent to the instant t₁ and prior to the instant t₄), the torque T_(E) generated by the internal combustion engine 4 starting from the instant t₃, if the instant t₅ is prior to the instant t₃ (according to FIG. 4), or starting from the instant t₅, if the instant t₅ is subsequent to the instant t₃; furthermore, the control unit 12 of the drivetrain 6 accelerates, in case the accelerator pedal 22 is pressed by the driver during the upshift in the instant t₅ (which is subsequent to the instant t₁ and prior to the instant t₄), the closing of the incoming clutch 16B starting from the instant t₃, if the instant t₅ is prior to the instant t₃ (according to FIG. 4), or starting from the instant t₅, if the instant t₅ is subsequent to the instant t₃.

The control method described above has different advantages.

First of all, the method to control the execution of a shift to a higher gear described above is very comfortable, as, since the transmission of the torque to the drive wheels 3 is never interrupted, it determines a comfortable longitudinal acceleration profile of the road vehicle: indeed, the longitudinal acceleration of the road vehicle gradually shifts, without gradient inversion, from an initial deceleration to a final deceleration, which is smaller than the previous one (in the upshift the gear ratio gets longer and, therefore, the engine brake has a less incisive effect on the dynamic of the road vehicle 1); in this way, the driver always has a feeling of continuous deceleration.

Furthermore, the method to control the execution of a shift to a higher gear described above does not generate any perceivable metal noise, as the two clutches 16A and 16B never are both open at the same time and, hence, the drivetrain 6 always is “under stress”; namely, backlashes are significantly reduced and, as a consequence, so are noises, since the gear trains of the drivetrain 6 always are “under stress”.

The method to control the execution of a shift to a higher gear described above also allows for the implementation of a new strategy (also called “change of mind”), which allows the torque T_(B) of the incoming clutch 16B to be adjusted if, during the upshift, the driver presses the accelerator pedal 22, thus allowing for a more prompt and quick response of the road vehicle 1 to the commands of the driver.

Finally, the control method described above is easy and economic to be implemented, since it does not require the installation of additional physical components and does not call for an expansion of the control unit 12 of the drivetrain 6, since no additional calculation ability is needed.

LIST OF THE REFERENCE NUMBERS OF THE FIGURES

-   1 road vehicle -   2 front wheels -   3 rear wheels -   4 engine -   5 drive shaft -   6 drivetrain -   7 transmission -   8 transmission shaft -   9 differential -   10 axle shafts -   11 engine control unit -   12 drivetrain control unit -   13 BUS line -   14 synchronization cable -   15 primary shafts -   16 clutches -   17 secondary shaft -   18 primary gear wheel -   19 secondary gear wheel -   20 synchronizers -   21 steering wheel -   22 accelerator pedal -   23 brake pedal -   24 upshift paddle shifter -   25 downshift paddle shifter -   ω_(E) rotation speed -   ω_(A) rotation speed -   ω_(B) rotation speed -   T_(E) torque -   T_(A) torque -   T_(B) torque -   α acceleration -   t₀ time instant -   t₁ time instant -   t₂ time instant -   t₃ time instant -   t₄ time instant -   t₅ time instant 

The invention claimed is:
 1. A method to control the execution of an upshift to a higher gear with a released accelerator pedal (22) in a drivetrain (6) provided with a dual-clutch, servo-assisted transmission (7), so as to upshift from a current gear (A) to a following gear (B), which is shorter than the current gear (A); the drivetrain (6) comprises the dual-clutch, servo-assisted transmission (7) having two primary shafts (15); at least one secondary shaft (17) connected to drive wheels (3); and two clutches (16A, 16B), each interposed between a drive shaft (5) of an internal combustion engine (4) and a corresponding primary shaft (15); the control method comprises the steps of: opening, in a first instant (t₁), an outgoing clutch (16A) associated with the current gear (A); closing, in the first instant (t₁), an incoming clutch (16B) associated with the following gear (B); synchronizing, between a second instant (t₂), which is subsequent to the first instant (t₁), and a third instant (t₄), which is subsequent to the second instant (t₂), a rotation speed (ω_(E)) of the internal combustion engine (4) with a rotation speed (ω_(B)) of the incoming clutch (16B), namely with the rotation speed (ω_(B)) imposed by the gear ratio of the following gear (B); completely opening, in the third instant (t₄), the outgoing clutch (16A); completely closing, in the third instant (t₄), the incoming clutch (16B); keeping a torque (T_(A)) transmitted by the outgoing clutch (16A) constant between the second instant (t₂) and a fourth instant (t₃), which is subsequent to the second instant (t₂) and prior to the third instant (t₄); and keeping a torque (T_(B)) transmitted by the incoming clutch (16B) constant between the second instant (t₂) and the fourth instant (t₃).
 2. The control method according to claim 1, wherein, between the second instant (t₂) and the fourth instant (t₃), the torque (TB) transmitted by the incoming clutch (16B) is smaller than the torque (TA) transmitted by the outgoing clutch (16A).
 3. The control method according to claim 1, wherein, between the fourth instant (t₃) and the third instant (t₄), the torque (T_(B)) transmitted by the incoming clutch (16B) is increased with a first linear ramp.
 4. The control method according to claim 3, wherein, between the fourth instant (t₃) and the third instant (t₄), the torque (T_(A)) transmitted by the outgoing clutch (16A) is decreased with a second linear ramp.
 5. The control method according to claim 1, wherein, in the first instant (t₁), the torque (T_(B)) transmitted by the incoming clutch (16B) is increased in a stepped manner.
 6. The control method according to claim 1, wherein, between the first instant (t₁) and the second instant (t₂), the torque (T_(A)) transmitted by the outgoing clutch (16A) is decreased with a third linear ramp.
 7. The control method according to claim 1, wherein the internal combustion engine (4) is in cut-off condition before the upshift to a higher gear and is in cut-off condition also after the upshift to a higher gear.
 8. The control method according to claim 7, wherein, before, during and after the upshift to a higher gear, a driver keeps the accelerator pedal (22) completely released.
 9. The control method according to claim 1 and comprising the further steps of: detecting a pressing of the accelerator pedal (22) exerted by a driver during the upshift to a higher gear; increasing, in case the accelerator pedal (22) is pressed by the driver during the upshift to a higher gear in a fifth instant (t₅) subsequent to the first instant (t1) and prior to the third instant (t₄), a torque (T_(E)) generated by the internal combustion engine (4) starting from the fourth instant (t₃), if the fifth instant (t5) is prior to the fourth instant (t₃), or starting from the fifth instant (t₅), if the fifth instant (t₅) is subsequent to the fourth instant (t₃).
 10. The control method according to claim 1 and comprising the further steps of: detecting a pressing of the accelerator pedal (22) exerted by a driver during the upshift to a higher gear; accelerating, in case the accelerator pedal (22) is pressed by the driver during the upshift to a higher gear in a fifth instant (t₅) subsequent to the first instant (t₁) and prior to the third instant (t₄), the closing of the incoming clutch (16B) starting from the fourth instant (t₃), if the fifth instant (t₅) is prior to the fourth instant (t₃), or starting from the fifth instant (t5), if the fifth instant (t₅) is subsequent to the fourth instant (t₃). 